Compressor assembly having electronics cooling system and method

ABSTRACT

A system, compressor, and method that cools an electronics module with a low-pressure refrigerant. The system, compressor, and method utilize a temperature sensor that detects a temperature of the low pressure refrigerant and communicates with the electronics module. Based on the temperature detected by the temperature sensor, the electronics module controls a liquid dry out point of the refrigerant that is used to cool the electronics module.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 12/244,387 filed on Oct. 2, 2008, now U.S. Pat. No. 8,826,682, which claims the benefit of U.S. Provisional Application No. 60/998,047 filed on Oct. 5, 2007. The entire disclosures of each of the above applications are incorporated herein by reference.

FIELD

The present disclosure relates to a compressor system that utilizes refrigerant to cool system electronics.

BACKGROUND

The statements in this section merely provide background information related to the present disclosure and may not constitute prior art.

A compressor may use electronics to control the compressor motor. The electronics may be externally mounted to the outer shell of the compressor, and used to modulate compressor capacity, such as by varying the speed of the motor. During operation, however, the electronics may generate heat. If too much heat is generated, the electronics may overheat.

SUMMARY

The present disclosure provides a system including a compressor having a suction side for receiving low-pressure refrigerant and a discharge side for dispensing high-pressure refrigerant. A pair of heat exchangers are in communication with the compressor, and an expansion valve is disposed between the heat exchangers. A temperature sensor detects a temperature of the low-pressure refrigerant passing through the system, and a cooling apparatus receives the low-pressure refrigerant. An electronics module is adjacent the cooling apparatus, in communication with the temperature sensor, and controls the expansion valve based on the temperature of the low-pressure refrigerant to control an amount of the low-pressure refrigerant passing through the cooling apparatus.

In the system described above, the electronics module controls a liquid dry out point (LDOP) of the low-pressure refrigerant.

Also, the electronics module controls superheating of the low-pressure refrigerant.

In the system described above, if the sensor detects a decrease in temperature of the low-pressure refrigerant, the electronics module causes the expansion valve to decrease an amount of refrigerant allowed to reach one of the heat exchangers.

If the sensor detects an increase in temperature of the low-pressure refrigerant, the electronics module causes the expansion valve to increase an amount of refrigerant allowed to reach one of the heat exchangers.

The temperature sensor may be disposed adjacent the cooling apparatus.

Alternatively, the temperature sensor may be disposed at an inlet of the cooling apparatus.

In yet another alternative, the temperature sensor is disposed downstream of an inlet of the cooling apparatus.

The cooling apparatus may include a cold plate having a plurality of passageways for carrying the low-pressure refrigerant.

Moreover, the compressor may be a variable speed compressor.

Further, the electronics module may include an inverter.

The present disclosure also provides a compressor for an air conditioning system or a heat pump system carrying a refrigerant. The compressor includes a shell including a suction line for receiving low-pressure refrigerant and a discharge line for dispensing high-pressure refrigerant. An electronics module is proximate the shell, and a cooling apparatus is proximate the electronics module that utilizes the low-pressure refrigerant to cool the electronics module. A temperature sensor is adjacent the cooling apparatus and in communication with the electronics module, and detects a temperature of the low-pressure refrigerant.

In the compressor described above, the cooling apparatus may include a cold plate having a plurality of passageways for carrying the low-pressure refrigerant.

In addition, the sensor may be located at an inlet to the cooling apparatus.

Alternatively, the temperature sensor may be disposed downstream of an inlet of the cooling apparatus.

In the compressor described above, the electronics module controls an amount of the refrigerant passing through the cooling apparatus.

If the sensor detects a decrease in temperature of the low-pressure refrigerant, the electronics module decreases an amount of low-pressure refrigerant passing through the cooling apparatus.

If the sensor detects an increase in temperature of the low-pressure refrigerant, the electronics module increases an amount of low-pressure refrigerant passing through the cooling apparatus.

The electronics module also controls a liquid dry out point (LDOP) of the refrigerant.

In addition, the electronics module controls superheating of the low-pressure refrigerant.

Moreover, the electronics module may vary a speed of the compressor.

Further, the electronics module may include an inverter.

The present disclosure also provides a method that includes monitoring a temperature of a low-pressure refrigerant with a temperature sensor in communication with an electronics module. The electronics module controls a flow of the low-pressure refrigerant based on the temperature, and the electronics module is cooled with the low-pressure refrigerant.

In the method, controlling the flow controls a liquid dry out point (LDOP) of the low-pressure refrigerant.

Moreover, controlling the LDOP controls superheating of the low-pressure refrigerant.

If the sensor detects a decrease in temperature of the low-pressure refrigerant, the electronics module decreases the flow of low-pressure refrigerant.

If the sensor detects an increase in temperature of the low-pressure refrigerant, the electronics module increases the flow of low-pressure refrigerant.

In addition, the electronics module may include an inverter.

The method may also include compressing the refrigerant with a variable speed compressor.

The present disclosure also provides a system including a compressor that discharges a high-pressure refrigerant. A pair of heat exchangers are in communication with the compressor. An expansion valve is disposed between the heat exchangers that converts the high-pressure refrigerant to a low-pressure refrigerant, and an electronics module controls the expansion valve. A temperature sensor is in communication with the module for detecting a temperature of the low-pressure refrigerant. A cooling apparatus is adjacent the temperature sensor for cooling the module with the low-pressure refrigerant, wherein if the sensor detects a decrease in temperature of the low-pressure refrigerant, the electronics module causes the expansion valve to decrease an amount of low-pressure refrigerant allowed to pass therethrough and, if the sensor detects an increase in temperature of the low-pressure refrigerant, the electronics module causes the expansion valve to increase an amount of low-pressure refrigerant allowed to pass therethrough.

In the above system, increasing and decreasing the refrigerant with the expansion valve controls a liquid dry out point (LDOP) of the refrigerant.

In addition, controlling the LDOP controls superheating of the low-pressure refrigerant.

In the system, the sensor may be disposed at an inlet of the cooling apparatus.

Alternatively, the sensor may be disposed downstream of an inlet of the cooling apparatus.

In the system, the compressor may be a variable speed compressor.

In addition, the electronics module may include an inverter.

Further areas of applicability will become apparent from the description provided herein. It should be understood that the description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.

DRAWINGS

The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.

FIG. 1 is a schematic representation of an air conditioning or heat pump system;

FIG. 2 is a perspective view of a compressor and its corresponding electronics module having a cooling apparatus; and

FIG. 3 is a cross-sectional view of a conduit in the air conditioning or heat pump system, illustrating the transition of the refrigerant from a liquid phase to a gaseous phase.

DETAILED DESCRIPTION

The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses. It should be understood that throughout the drawings, corresponding reference numerals indicate like or corresponding parts and features.

FIG. 1 is a schematic representation of an air conditioning or heat pump system 10. Air conditioning or heat pump system 10 may generally include a compressor 12, a condenser 14, and an evaporator 16. Disposed between condenser 14 and evaporator 16 may be an expansion valve 18. Air conditioning or heat pump system 10 may also be provided with a reversing valve 20 where suction and discharge lines 22 and 24, respectively, pass through. Reversing valve 20 allows system 10 to operate as either a refrigeration system or a heat pump. Regardless whether system 10 operates as a refrigeration system or as a heat pump, compressor 12 receives low-pressure refrigerant at a suction side and dispenses high-pressure refrigerant at a discharge side.

When operating as a refrigeration system, system 10 uses the cooling effect of evaporation of the refrigerant to lower the temperature of the surroundings near one heat exchanger (i.e., evaporator 16) and uses the heating effect of high pressure, high temperature gas to raise the temperature of the surroundings near another heat exchanger (i.e., condenser 14). This is usually accomplished by releasing a refrigerant under pressure (usually in a liquid phase) into a low pressure region to cause the refrigerant to expand into a low temperature mixture of liquid and vapor. Commonly, this low pressure region comprises a coil (not shown) that acts as an evaporator, that may be formed in evaporator 16. Once in the evaporator coil, the refrigerant mixture may exchange heat with the tubing of the coil, which in turn exchanges heat with high temperature ambient air of the region desired to be cooled. Evaporation of refrigerant from liquid to gas absorbs heat from the ambient air and thereby cools it.

Release of refrigerant into the low pressure evaporator coil is usually metered by expansion valve 18. There are a wide variety of different types of expansion valves in use today, ranging from simple non-adjustable capillary tubes or orifices to electrically adjustable valves, such as pulse width modulated valves and stepper motor valves.

The refrigerant at the output of evaporator 16 is compressed back into a high pressure state by compressor 12 and is condensed into a liquid phase by condenser 14 so that it may be used again. In some systems, compressor 12 may be variable speed or variable capacity, so that the compressor 12 also controls the rate at which refrigerant flows through the restricted orifice. To operate compressor 12 at variable speed or variable capacity, compressor 12 may include an electronics module 26, including an electronic inverter.

Electronic inverter, which may also be referred to as a variable frequency drive (VFD), receives electrical power from a power supply and delivers electrical power to compressor 12. By modulating the frequency of electrical power delivered to the electric motor of compressor 12, inverter may thereby modulate and control the speed, and consequently the capacity, of compressor 12. To modulate the frequency of electric power, inverter may include solid state electronics to modulate the frequency of electrical power. Generally, inverter more specifically comprises a converter that converts the inputted electrical power from AC to DC, and then inverter converts the electrical power from DC back to AC at a desired frequency.

FIG. 2 illustrates an exemplary compressor 12 having electronics module 26 mounted thereto. Electronics module 26 includes an electrical enclosure or housing 28 that houses various electronic components such as a control module 30. Control module 30, such as Assignee's U.S. Pat. No. 6,302,654, which is hereby incorporated by reference in its entirety, may control compressor capacity or monitor operating conditions of the compressor.

Control module 30 may generally include a control block, microprocessor, memory analog-to-digital converters, a communication interface, the inverter described above, and a plurality of terminals connected to various sensors that monitor parameters of the compressor. The control block, which includes processing circuitry, may control compressor capacity. The analog-to-digital converter may be used to convert analog signals sent by the various sensors to a digital signal before input into control module 30. The communication interface may provide communication with the control block from an outside source or server via, for example, an internet or intranet connection.

Electronics module 26 may also house a compressor protection or diagnostic system that may include controller 30, such as that described above, and a power interruption system (not shown). Diagnostic system may include a plurality of sensors, and diagnoses operating conditions by receiving and analyzing motor, compressor, and system parameters. In addition, the diagnostic data may be used to control compressor modulation based on system conditions detected by the sensors. An exemplary compressor protection and control diagnostic systems is described in the assignee's commonly owned U.S. patent application Ser. No. 11/059,646 filed on Feb. 16, 2005, and U.S. Pat. No. 6,615,594 which are hereby incorporated by reference in their entirety.

As system 10 operates, the components of electronics module 26 may generate heat. As more heat is generated, however, the components (e.g., inverter components) of electronics module 26 may overheat and cause system 10 to either shutdown or reduce capacity until the components cool, or the components may not operate correctly and cause system 10 to malfunction or fail. To reduce the possibility that the components of electronics module 26 may fail due to overheating, steps may be taken to cool electronics module.

Again referring to FIG. 2, a cooling apparatus 50 may be mounted to electronics module 26 to cool electronics module 26. Cooling apparatus 50 may be a cold plate that may include a generally planar member 52 that includes a plurality of pathways 54. The pathways 54 are configured to support a tubular assembly 56 that carries the refrigerant therein. Refrigerant passing through tubular assembly 56 and planar member 52 absorbs heat generated by the electronics module 26 that is passed from the electronics assembly 26 to planar member 52. In this manner, heat generated by the electronics module 26 may be efficiently transferred to the refrigerant (i.e., a suction gas) flowing through the cooling apparatus 50 to cool electronics module 26.

At an inlet 58 of cooling apparatus 50 within a suction line 60 from system 10 may be disposed a temperature sensor 62. Although temperature sensor 62 is illustrated as being disposed upstream at inlet 58 in FIG. 2, the present disclosure should not be limited thereto. Temperature sensor 62, rather, may be disposed upstream of inlet 58, adjacent inlet 58, or downstream of inlet 58 within cooling apparatus 50. Regardless, temperature sensor 62 senses a temperature of the suction line 60 refrigerant, indicating conditions prior to or after the refrigerant enters cooling apparatus 50, and communicates temperatures of the refrigerant in suction line 60 to electronics module 26. Fluctuations in temperature of the refrigerant detected by temperature sensor 62 and communicated to electronics module 26 may by used to control expansion valve 18 to either increase or decrease the amount of refrigerant entering evaporator 16. That is, electronics module 26 is also in communication with expansion valve 18 to control an amount of refrigerant entering evaporator 16 through expansion valve 18. By controlling expansion valve 18 based on a temperature of the refrigerant detected by temperature sensor 62, the amount of refrigerant entering evaporator 16 may be controlled to enhance the cooling effect of cooling apparatus 50 on electronics module 26.

Furthermore, by controlling expansion valve 18, a liquid dry out point (LDOP) of the refrigerant in system 10 may be controlled. LDOP is described in assignee's U.S. Pat. No. 5,502,970, which is hereby incorporated by reference in its entirety. LDOP operates on a principle that a refrigerant flow pattern develops as the refrigerant acquires heat in the coils 64 of evaporator 16 and ultimately makes a transition from liquid to vapor. Referring to FIG. 3, a section of the evaporator coil 64 of evaporator 16 is illustrated. Specifically, a portion adjacent to an exit end of coil 64 has been illustrated, in magnified form, to show how the refrigerant changes state as heat is absorbed.

In Region a, the refrigerant is principally in the liquid phase with some suspended bubbles of refrigerant in the vapor phase. The bubbles tend to flow along the top of the coil, as illustrated. As heat is absorbed, the refrigerant gradually exhibits the flow illustrated in Region b. In Region b, bullet-shaped bubbles form and tend to move along the top of the coil as illustrated.

As the flow proceeds to Region c, the refrigerant enters a stratified flow regime, characterized by liquid refrigerant flowing along the bottom of the coil and vapor refrigerant flowing along the top. As further heat energy is absorbed by the refrigerant, the liquid refrigerant develops waves that are depicted in Region d. These waves are formed on the liquid/vapor interface through the increased velocity of the vaporous refrigerant.

Next, the slug flow regime develops as illustrated in Region e. The waves and the liquid refrigerant grow large enough to touch the upper surface of the coil, with large frothy slugs of liquid interspersed with regions of stratified liquid flow. Finally, in Region f virtually all of the refrigerant is in the vapor phase and the flow become annular. The liquid refrigerant adheres to the sidewall of the coil with a greater quantity present at a bottom of a coil due to gravitational effect.

The LDOP or “burn out” point occurs when the liquid phase adhering to the sidewalls substantially disappears. The LDOP is illustrated generally at Region g in FIG. 3. The precise location of the LDOP, however, will shift randomly or erratically back and forth (i.e., left to right in FIG. 3) as system 10 operates.

Utilizing the LDOP concept, sensor 62 is disposed at a location adjacent inlet 58 of cooling apparatus 50 so that if a minimum amount of liquid refrigerant advances to the location of sensor 62 (i.e., the LDOP moves downstream of sensor 62 towards cooling apparatus 50), a sudden change of temperature may be detected by sensor 62 (because liquid refrigerant generally has a temperature less than gaseous refrigerant). If such a change in temperature is detected by sensor 62 and communicated to electronics module 26, electronics module 26 may then communicate with expansion valve 18 to reduce the amount of refrigerant flowing to evaporator 16. Reducing the amount of refrigerant flowing to evaporator 16 may move the LDOP upstream of sensor 62.

In contrast, when the temperature of the refrigerant detected by sensor 62 increases, indicating that the LDOP is upstream of sensor 62, expansion valve 18 may be controlled by electronics module 26 to increases the flow of the refrigerant to evaporator 16 to move the LDOP back downstream towards sensor 62. In this manner, the refrigerant flow may be controlled through evaporator 16 to control the LDOP by controlling expansion valve 18. By controlling the LDOP such that the LDOP is essentially at the location of sensor 62, a minimum amount of liquid refrigerant may enter cooling apparatus 50.

Controlling expansion valve 18 based on fluctuation of the LDOP also allows for minimum superheating of the refrigerant, which improves performance of the heat exchange surface of evaporator 16. This, in turn, enables the size of evaporator 16 to be minimized. Furthermore, due to the minimum superheating of the refrigerant, lower temperature cooling of the electronic module 26 may be achieved. This lower temperature cooling of electronics module 36, compared to using condensed liquid as used in conventional refrigerant systems, may result in lower cost electronics. Moreover, controlling expansion valve 18 so that the LDOP stays upstream of cooling apparatus 50 minimizes temperature fluctuations experienced by electronics module 26.

Additionally, condensation that may form on electronics module 26 and cooling apparatus 50 may be kept minimal since electronics module 26 may be cooled in accordance with operation of compressor 12. That is, as capacity of compressor 12 increases, operation of expansion valve 18 may be controlled to maximize the amount of refrigerant entering evaporator 16 and cooling apparatus 50 to cool electronics module 26.

Using LDOP also enables cooling apparatus 50 to be sized such that minimization of electronics module 26 is possible by ensuring lower solid-state electronic component (not shown) junction temperature. Electronics module 26 used by system 10 may have electronic components with a maximum current rating limited by its junction temperature, T_(J). In general, T_(J) should not exceed 160 degrees C. and, generally, T_(J) is about 150 degrees C. at a given solid-state packaging case temperature, T_(C). Case temperature affects the maximum current rating of the solid-state switch. For example, the solid-state switches may be rated at 60 amperes at a T_(C) of 25 degrees C. and rated at 30 amperes at a T_(C) of 100 degrees C. This difference in current rating results from thermal resistance at the junction of the solid-state switch and its packaging.

A T_(C) of 25 degrees Celsius may not be obtained at full current rating using only forced convection of air on a typical heat sink in contact with the packaging case, let alone by using natural convection. T_(C) of 100 degrees C., however, is more readily observed using these methods and, therefore, current ratings of about 30 amperes are generally achieved using forced convection and natural convection of air on a heat sink with contact with the packaging case. By using refrigerant cooling and controlling the LDOP by controlling the expansion valve 18, however, the amount of cooling that cooling apparatus 50 may exhibit on electronics module 26 and housing 28 may extend the current rating to about 39 amperes (i.e., a 30 percent increase). That is, cooling apparatus 50 having gaseous refrigerant passing therethrough based on controlling the LDOP results in a lower electronic component junction temperature that allows solid-state switch, and therefore electronics module 26, to operate at a higher current rating. Because the current rating may be raised in this manner, the cost of running system 10 may be reduced, and the cost of the electronics used for electronics module 26 may be reduced

The above description is merely exemplary in nature and, thus, variations that do not depart from the gist of the disclosure are intended to be within the scope of the present teachings. Such variations are not to be regarded as a departure from the spirit and scope of the present teachings. 

What is claimed is:
 1. A system comprising: a compressor having a suction side for receiving low-pressure refrigerant and a discharge side for dispensing high-pressure refrigerant; a pair of heat exchangers in communication with said compressor; an electronics module associated with the compressor; a cooling apparatus mounted to the electronics module that receives said low-pressure refrigerant to cool said electronic module; a temperature sensor located at an inlet of said cooling apparatus, said temperature sensor for detecting a temperature of said low-pressure refrigerant entering said cooling apparatus, wherein control of said expansion valve is based on said temperature of said low-pressure refrigerant to minimize an amount of said low-pressure refrigerant in a liquid phase passing through said cooling apparatus.
 2. The system of claim 1, wherein control of said expansion valve controls a liquid dry out point of said low-pressure refrigerant.
 3. The system of claim 1, wherein control of said expansion valve controls superheating of said low-pressure refrigerant.
 4. The system of claim 1, wherein if said sensor detects a decrease in temperature of said low-pressure refrigerant, said expansion valve is controlled to decrease an amount of refrigerant allowed to reach one of said heat exchangers.
 5. The system of claim 1, wherein if said sensor detects an increase in temperature of said refrigerant, said expansion valve is controlled to increase an amount of refrigerant allowed to reach one of said heat exchangers.
 6. The system of claim 1, wherein a first of said pair of heat exchangers receives said high-pressure refrigerant and a second of said pair of heat exchangers receives said low-pressure refrigerant, said cooling apparatus is located in series between said second heat exchanger and said compressor.
 7. A compressor for an air conditioning system or a heat pump system carrying a refrigerant, comprising: a shell including a suction line for receiving low-pressure refrigerant and a discharge line for dispensing high-pressure refrigerant; an electronics module associated with the compressor; a cooling apparatus mounted to said electronics module that utilizes said low-pressure refrigerant to cool said electronics module; an expansion valve for controlling an amount of said low-pressure refrigerant entering the cooling apparatus; and a temperature sensor at an inlet of said cooling apparatus for detecting a temperature of said low-pressure refrigerant entering said cooling apparatus, wherein control of said expansion valve is based on said temperature of said low-pressure refrigerant to minimize an amount of said low-pressure refrigerant in a liquid phase passing through the cooling apparatus.
 8. The compressor of claim 7, wherein if said sensor detects a decrease in temperature of said low-pressure refrigerant, said expansion valve decreases an amount of low-pressure refrigerant passing through said cooling apparatus.
 9. The compressor of claim 7, wherein if said sensor detects an increase in temperature of said low-pressure refrigerant, said expansion valve increases an amount of low-pressure refrigerant passing through said cooling apparatus.
 10. The compressor of claim 7, wherein said expansion valve controls a liquid dry out point of the refrigerant.
 11. A method comprising cooling an electronics module that is associated with a compressor using a cooling apparatus mounted to said electronics module with a low-pressure refrigerant that passes through said cooling apparatus, said step of cooling including monitoring a temperature of said low-pressure refrigerant with a temperature sensor located at an inlet of said cooling apparatus, and controlling an expansion valve based on said temperature to minimize an amount of said low-pressure refrigerant in a liquid phase passing through said cooling apparatus.
 12. The method of claim 11, wherein controlling said expansion valve controls a liquid dry out point of said low-pressure refrigerant.
 13. The method of claim 11, wherein controlling said liquid dry out point controls superheating of said low-pressure refrigerant.
 14. The method of claim 11, wherein if said sensor detects a decrease in temperature of said low-pressure refrigerant, said expansion valve decreases said flow of low-pressure refrigerant.
 15. The method of claim 11, wherein if said sensor detects an increase in temperature of said low-pressure refrigerant, said expansion valve increases said flow of low-pressure refrigerant.
 16. A system comprising: a compressor that discharges a high-pressure refrigerant; a pair of heat exchangers in communication with said compressor; an expansion valve disposed between said heat exchangers that converts said high-pressure refrigerant to a low-pressure refrigerant; an electronics module associated with said compressor; a cooling apparatus mounted to said electronics module for cooling said electronics module with said low-pressure refrigerant; and a temperature sensor located at an inlet of said cooling apparatus for detecting a temperature of said low-pressure refrigerant entering said cooling apparatus to cool said electronics module, wherein if said sensor detects a decrease in temperature of said low-pressure refrigerant entering said cooling apparatus, said expansion valve is controlled to decrease an amount of low-pressure refrigerant allowed to pass therethrough; wherein if said sensor detects an increase in temperature of said low-pressure refrigerant entering said cooling apparatus, said expansion valve is controlled to increase an amount of low-pressure refrigerant allowed to pass therethrough; and control of said expansion valve minimizes said low-pressure refrigerant in a liquid phase passing through said cooling apparatus.
 17. The system of claim 16, wherein increasing and decreasing said refrigerant with said expansion valve controls a liquid dry out point of said refrigerant.
 18. The system of claim 16, wherein controlling said liquid dryout point controls superheating of said low-pressure refrigerant.
 19. The system of claim 16, wherein said compressor is a variable speed compressor.
 20. The system of claim 16, wherein said electronics module includes an inverter. 